Metering method and control apparatus for injection molding machine

ABSTRACT

When a metering process is started, a screw rotates at a preset rotating speed, thereby carrying out back pressure control to keep the pressure of a resin at a preset pressure, and retreats. When the screw is located near a preset metering completion position, the control mode is switched to positioning control for the preset metering completion position, and a screw rotation stop command is outputted. The screw overruns for some distance before its rotation stops after it retreats and stops at the preset metering completion position. A resin quantity for the overrun is corrected to obtain a preset metered resin quantity by reversely rotating the screw by a rotational amount corresponding to the overrun.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No. 10/702,519filed Nov. 7, 2003 which is currently pending.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an injection molding machine, and moreparticularly, to a metering method capable of accurately metering aresin and a control apparatus for the injection molding machine.

2. Description of the Related Art

In an in-line screw-type injection molding machine, a screw in a heatingcylinder is rotated to melt and knead a resin material, and the moltenresin is supplied under pressure to the distal end portion of theheating cylinder. Pressure control is carried out as the screw retreats.When the screw reaches a preset metering point, its rotation and retreatare stopped, and the resin is metered. In a pre-plasticization-typeinjection molding machine, a screw is rotated for pre-plasticization,and a molten resin is supplied to the distal end portion of thecylinder. A plunger retreats under the pressure of the resin that issupplied to the distal end portion of the cylinder. When the plungerreaches a preset position, the molten resin is metered. After thismetering operation, the screw or plunger is advanced so that the moltenresin is injected into a mold to fill it.

In order to enhance the quality of molded parts, variation of the fillof the molten resin in the mold must be reduced.

Injection is carried out after the screw or plunger retreats to theposition of the metering point. If the metered molten resin is directlyinjected into the mold to fill it as this is done, an accurate fill canbe obtained, so that the quality of the molded parts can be kept uniformwithout any variation in the weight of the molded parts. In this case,however, the metered resin quantity changes as an injection process isstarted after the metering operation is finished, so that an accuratemolten resin quantity cannot be injected. Various techniques have beenproposed to solve this problem.

In the metering process, the molten resin that is produced as the screwrotates is supplied to the distal end portion of the cylinder. A valve,such as a check valve or check ring, is provided on the distal end ofthe screw, whereby the molten resin at the distal end portion of thescrew can be injected into the mold without flowing backward in theinjection process. According to a proposed technique, the molten resinmoves between the distal and rear end portions of the screw through thevalve during the time interval between the end of the metering operationand the start of the injection. Thus, the metered resin quantity can beprevented from changing, so that the accurately metered resin can beinjected.

(a) In the pre-plasticization type injection molding machine, theplunger retreats so that the pressure of the molten resin at the distalend portion of the screw is zero after the metering operation isfinished. Thereafter, the plunger is advanced, and the check valve iscauses to retreat to close a resin passage from the rear end portion ofthe cylinder to its distal end portion. Thus, the molten resin can beprevented from flowing backward, so that variation of the metered resinquantity can be eliminated (e.g., Japanese Patent Application Laid-openNo. 2-147312).

(b) If the screw retreats to the metering point, in the in-lineinjection molding machine, its rotation and retreat are stopped.Thereafter, the screw is rotated reversely to lower the resin pressureat the rear end portion of the cylinder so that the check valve retreatsto close the resin passage. Injection is started after the resin issucked back. By doing this, variation of the metered resin quantity canbe eliminated (e.g., Japanese Patent Application Laid-open No.11-240052).

(c) Likewise, the screw is rotated reversely after the meteringoperation is finished, or the resin is sucked back as the screw isrotated reversely, and the resin passage is closed by means of the checkring. Injection is started thereafter (e.g., Japanese Patent ApplicationLaid-open No. 10-16016).

(d) After the metering operation is finished, moreover, the resin issucked back, the screw is then rotated reversely, and the resin passageis closed by means of the ring valve. Injection is carried outthereafter (e.g., Japanese Patent Application Laid-open No. 9-29794).

According to the conventional technique described above, fluctuation ofthe metered resin quantity that is attributable to, for example, abackflow of the molten resin at the distal end portion of the cylinderduring the injection can be prevented.

The following is a description of a control technique that ensures anaccurate metered resin quantity.

(a) A plurality of sets of back pressure commands and screw rotationalfrequency commands are prepared, and the combined back pressures andscrew rotational frequencies are controlled in association with oneanother. When the metering process is finished, the screw rotationalfrequency and the screw retreating speed controlled and adjusted tozero, whereby the metering is made uniform (e.g., Japanese ExaminedPatent Publication No. 1-26857).

(b) Further, a stable metered resin quantity can be obtained bygradually lowering the screw rotating speed used before the meteringoperation is stopped with respect to a retreat position of the screw(e.g., Japanese Examined Patent Publication No. 64-6931).

The screw, a motor that rotates the screw, and a transmission mechanismthat transmits motor torque to the screw have inertia. If the motor forscrew rotation is stopped to interrupt the screw rotation when the screwreaches the position of the metering point, therefore, the screwrotation cannot be stopped in a moment under the influence of theinertia. Thus, the inertia causes the screw and the screw rotatingmechanism to overrun. Thereupon, the resin quantity changescorrespondingly, so that the metered resin quantity fails to be equal toa preset value. Since this metered resin quantity that causes theoverrun is not controlled, it is only apparently stable, and fluctuatesactually. In consequence, the actual weight of molded parts varies.

If a high screw rotational frequency is used with the same presetmetering completion position, it takes much time to stop the screw, sothat the metered resin quantity involves a surplus quantity that isattributable to the overrun. Therefore, the metered resin quantity isliable to increase and may vary depending on the molding conditions.Thus, settling the molding conditions requires an extra hard operation,such as fine adjustment of the preset metering completion position.Further, the aforesaid method in which the rotational frequency of thescrew is gradually lowered as the metering completion position isapproached requires time. In consequence, the metering process takes toomuch time.

SUMMARY OF THE INVENTION

A first mode of a metering method for an injection molding machineaccording to the present invention comprises: obtaining a screwrotational amount after a screw or a plunger retreats up to a presetmetering completion position; and reversely rotating the screw by theobtained rotational amount after the rotation of the screw is stopped.

A second mode of the metering method for an injection molding machineaccording to the present invention comprises: delivering a screwrotation stop command to screw rotation drive means when a screw or aplunger stops after retreating and reaching a preset metering completionposition, and measuring the rotational amount of the screw thereafter;and reversely rotating the screw by the measured rotational amount afterthe rotation of the screw is stopped.

A third mode of the metering method for an injection molding machineaccording to the present invention comprises: delivering a screwrotation stop command to screw rotation drive means when a screw or aplunger stops after retreating and reaching a preset metering completionposition, and measuring and storing the rotational amount of the screwthereafter; and delivering the screw rotation stop command to the screwrotation drive means when the screw or the plunger stops afterretreating and reaching the preset metering completion position, in asubsequent metering process, and reversely rotating the screw by thestored rotational amount after the rotation of the screw is stopped.

A control apparatus for an injection molding machine is applied to anin-line injection molding machine, which comprises a screw advancing andretreating motor for advancing and retreating a screw and a screwrotating motor for rotating the screw, and is designed so that the screwrotating motor is rotated in a given direction during metering operationas the screw advancing and retreating motor is driven to cause the screwto retreat to a preset metering completion position.

A first mode of the control apparatus comprises: means for obtaining arotational amount which represents overrun of the screw during the timefrom the arrival of the screw at the preset metering completion positionto the subsequent deceleration and stop of the screw rotation; and meansfor driving the screw rotating motor to rotate the screw in a directionopposite to the direction for the metering operation in accordance withthe obtained rotational amount.

Further, a second mode of the control apparatus comprises: means forpreviously setting and storing a rotational amount which representsoverrun of the screw during the time from the arrival of the screw atthe preset metering completion position to subsequent deceleration andstop of the screw rotation; and means for driving the screw rotatingmotor to rotate the screw for the stored rotational amount in adirection opposite to the direction for the metering operation after thescrew rotation is stopped at the end of the metering operation.

The first and second modes of the control apparatus may assume thefollowing aspects.

The means for rotating the screw in the direction opposite to thedirection for the metering operation may reversely rotate the screwimmediately after the screw rotation is stopped.

The means for rotating the screw in the direction opposite to thedirection for the metering operation may drive the screw rotating motorto rotate the screw at a preset rotating speed in the direction oppositeto the direction for the metering operation.

The in-line injection molding machine may be replaced with aplunger-type injection molding machine, the screw advancing andretreating motor for advancing and retreating the screw may be replacedwith a plunger advancing and retreating motor for advancing andretreating a plunger, and the plunger may be advanced and retreated inplace of the screw by means of the plunger advancing and retreatingmotor.

According to the present invention, there may be provided a meteringmethod in which fluctuation of a metered resin quantity that isattributable to overrun of screw rotation can be corrected to obtain amore accurate, uniform metered resin quantity, and a control apparatusfor an injection molding machine.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects and features of the invention will be moreapparent from the ensuing description taken in connection with theaccompanying drawings, in which:

FIG. 1 is a schematic view of an injection mechanism of an injectionmolding machine to which various embodiments of the invention areapplied;

FIG. 2 is a block diagram showing the principal part of a controlapparatus according to one embodiment of the invention for controllingthe injection molding machine;

FIGS. 3A and 3B are diagrams illustrating the principle of operation ofthe invention; and

FIG. 4 is a flowchart illustrating operation according to one embodimentof the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a schematic diagram of the injection mechanism part of oneexample of an in-line type injection molding machine to which thecontrol device of the present invention is applied. In this figure, 1indicates a metal mold, 2 indicates a cylinder, 3 indicates a screw, 4indicates a hopper which supplies resin pellets to the interior of thecylinder, 5 indicates a front plate that forms the injection mechanism,and 6 indicates a rear plate. Furthermore, a plurality of guide bars 7are disposed between the abovementioned front plate 5 and rear plate 6,and a pusher plate 8 is disposed so that this plate can freely move inthe forward-rearward direction (left-right direction in the figure)while being guided by these guide bars 7.

The base part of the screw 3 is attached to the abovementioned pusherplate 8 so that the screw 3 is free to rotate, and a driven pulley 12 isattached to this base part. The screw 3 is rotationally driven by ascrew rotating servo motor M1 via a driving pulley 14, timing belt 13and the abovementioned driven pulley 12. Furthermore, the screw rotatingservo motor M1 is omitted from the figure; however, this motor isattached to the pusher plate 8 and advances and retreats together withthe pusher plate 8.

Furthermore, a ball nut 10 is attached to the pusher plate 8 via apressure sensor (load cell) 9; a ball screw 11 is screw-engaged withthis ball nut 10, and this ball screw 11 is rotationally driven by ascrew advancing and retreating servo motor M2 via a driving pulley 15,timing belt 16 and driven pulley 17. As a result, the screw 3 is drivenin the axial direction (left-right direction in the figure) via thepusher plate 8.

FIG. 2 is a block diagram of the essential parts of the control devicethat controls this injection molding machine; the control device of thepresent invention is constructed from this control device shown in FIG.2.

In FIG. 2, the symbol 26 indicates a processor which controls thisinjection molding machine as a whole; an A/D converter 20 which convertsanalog signals into digital signals, servo interfaces 21 and 22, aninput-output interface 25, and a memory 27 constructed from a ROM, RAM,nonvolatile RAM or the like are connected to this processor via a bus29. The pressure sensor (load cell) 9 is connected to the A/D converter20, and servo amplifiers 23 and 24 are respectively connected to theservo interfaces 21 and 22.

The servo motor M1 and a position/speed detector P1 are connected to theservo amplifier 23. The position and rotational speed of the servo motorM1 are detected by the abovementioned position/speed detector P1, sothat the amount of rotation and rotational speed of the screw 3 aredetected. The servo amplifier 23 receives movement commands issued bythe processor 26 during metering via the servo interface 21, andcontrols the driving of the servo motor M1 by performing feedbackcontrol of the speed, and also performing feedback control of thecurrent (torque), in accordance with the actual speed of the servo motorM1 (rotational speed of the screw) that is detected by theposition/speed detector P1 and fed back. The present invention ischaracterized in that control of a rotation amount (or control ofposition) is performed with a movement command, issued from theprocessor 26, which has a predetermined rotation amount with thedirection reversed with respect to the direction during metering.

Furthermore, the servo motor M2 and a position/speed detector P2 such asan encoder or the like are connected to the servo amplifier 24. Therotational position and rotational speed of the servo motor M2 aredetected by this position/speed detector P2, so that theadvancing/retreating position and advancing/retreating speed of thescrew 3 are detected. The servo amplifier 24 receives position commandsor speed commands output by the processor 26 via the servo interface 22,and controls the driving of the servo motor M2 by performing feedbackcontrol of the position and/or speed, and also performing feedbackcontrol of the current (torque), in accordance with the rotationalposition and/or actual speed of the servo motor M2 (speed to the screw)that is detected and fed back by the position/speed detector P2.Furthermore, the servo amplifiers 23 and 24 may be constructed fromhardware alone such as electrical circuits or the like; in the presentembodiment, however, these servo amplifiers are constructed fromso-called digital servo amplifiers which are formed by a processor, ROM,RAM or the like, and which control the position, speed, torque and thelike of the servo motors by means of software.

A data input-output device 28 comprising display means constructed froma liquid crystal display or CRT is connected to the input-outputinterface 25, and the setting of various commands, various parametersand the like can be performed by this input-output device 28, so thatvarious set values, the screw rpm, the screw retreat position and thelike (described later) can be displayed by the display means.

The abovementioned construction is the same as the construction in aconventional injection molding machine control device; however, thiscontrol device differs from a conventional injection molding machinecontrol device in that the device comprises functional means forcontrolling the resin pressure in the metering process, and performingcontrol so that the retreat of the screw and the rotation of the screwboth stop when metering is completed.

FIGS. 3A and 3B are diagrams illustrating the principle of the presentinvention. In FIG. 3A, the axes of ordinate and abscissa represent theretreating speed of the screw and time, respectively. In FIG. 3B, theaxes of ordinate and abscissa represent the rotating speed of the screwand time, respectively.

When a metering process is started, the screw is accelerated to a presetrotating speed and maintains the preset speed. A molten resin issubjected to back pressure control and kept at a preset back pressure.In consequence, the screw retreats substantially at a constant speed.

When a preset position deviation Ss is reached by a residual movement(position deviation) to a preset metering completion position Sb, thecontrol mode is switched to positioning control for the preset meteringcompletion position Sb, and a screw rotation stop command is outputted.The screw retreating speed is reduced and the screw is situated in thepreset metering completion position Sb, whereupon its retreat isstopped. In some cases, the metering process may be divided into aplurality of stages so that the screw rotating speed and screwretreating speed (back pressure) can be changed as the screw iscontrolled.

If the rotation of the screw is stopped in response to the screwrotation stop command, on the other hand, the screw rotation cannot stopimmediately, owing to the respective inertias of a motor, screw, screwrotation drive mechanism, etc. Thus, the screw rotation fails to stopwhen the screw retreat stops, as shown in FIG. 3B. In other words, thescrew overruns before its rotation stops. Accordingly, the resin issupposed to be overly metered by a rotational amount Aa corresponding tothe overrun. If this quantity is injected, it is larger than a presetmetered resin quantity. Since the rotational amount Aa corresponding tothe overrun is not controlled, moreover, it may possibly vary with everymetering process, thereby causing variation in the weight of moldedparts.

According to the present invention, therefore, the rotational amount Aacorresponding to the overrun is measured, and the screw is rotatedreversely by a amount Ab corresponding to the rotational amount Aa. Inconsequence, the molten resin that is accumulated and compressed on thedistal end portion of the screw of the injection cylinder is refluxedtoward the screw by an amount corresponding to the reverse rotationalamount Ab or the overrun rotational amount Aa. When injection isstarted, the surplus resin quantity that is attributable to the overrunis corrected by the reverse rotation, and the preset metered resinquantity is injected. Thus, the variation in the weight of molded partscan be reduced.

FIG. 4 is a flowchart showing the metering process the processor 26 ofthe control apparatus according to the present embodiment executes inaccordance with the aforesaid principle of the invention.

When the metering process is started, the processor 26 delivers amovement for the retreat of the screw to the preset metering completionposition Sb to the screw advancing and retreating servomotor M2 throughthe servo interface 22 (Step T1). This movement is loaded into an errorregister that is provided for position loop control in the servoamplifier 24.

Further, a resin pressure Pa that is detected by means of the pressuresensor (load cell) 9 through the A/D converter 20 is read, and a screwretreat command is obtained in accordance with a deviation between apreset resin pressure Ps and the detected resin pressure, and isdelivered to the servo amplifier 24 through the servo interface 22 (StepT2). First, movement to the metering completion-position Sb is loadedinto the error register in the servo amplifier 24. However, the positionloop control based on the position deviation stored in the errorregister is not carried out, and the screw advancing and retreatingservomotor M2 is drivingly controlled in accordance with the movementcommand based on the pressure deviation.

Further, a command for the rotation of the screw at the preset rotatingspeed is delivered to the servo amplifier 23 through the servo interface21 (Step T3).

On receiving the retreat command based on the pressure deviation, theservo amplifier 24 carries out speed feedback control in accordance withthe retreat command and the speed information fed back from the speeddetector P2, thereby moving the screw advancing and retreatingservomotor M2. Thus, back pressure control based on feedback control ofthe resin pressure is carried out.

On receiving the screw rotation command, moreover, the servo amplifier23 carries out speed feedback control in accordance with the commandedrotating speed and the speed information fed back from theposition/speed detector P1, thereby rotating the screw rotatingservomotor M1 at a preset speed.

Thus, the screw retreats as it carries out the pressure control andstarts rotation at the preset rotating speed, as shown in FIGS. 3A and3B, thereby melting and kneading the resin.

Then, the processor 26 subtracts the position information fed back fromthe position/speed detector P2, reads a value Sd of an error registerthat stores a current position deviation (Step T4), and compares it withthe position deviation Ss that is set as a rotating speed regulationpoint and a switching point from the pressure control to the positioningcontrol (Step T5).

If the read current position deviation Sd is greater than the presetposition deviation Ss, the program returns to Step T2, whereupon theprocesses of Steps T2 to T5 are repeatedly executed so that the positiondeviation Sd is not greater than the preset position deviation Ss.Thereupon, the screw 3 retreats at the retreating speed based on thepressure deviation, as shown in FIG. 3A, and goes on rotating at thepreset speed, as shown in FIG. 3B.

If the position deviation Sd is reduced to the preset position deviationSs or less, the movement command based on the pressure deviation isstopped (or pressure feedback control is stopped). Then, the controlmode is switched to the position loop control based on the positiondeviation (residual movement in the preset metering completion positionSb) stored in the error register, and the positioning control is started(Steps T6 and T7). Further, the rotation stop command (for stopping thespeed command) is delivered to the servo amplifier 23 of the screwrotating servomotor M1 (Step T8). The preset position deviation Ss ispreviously obtained and set as a value corresponding to a movement fromthe start of deceleration to the stop, based on a previously measuredscrew retreating speed and the acceleration-deceleration time constantof the screw advancing and retreating servomotor M2. Alternatively, theactual screw retreating speed may be detected so that a movementrequired for the deceleration and stopping can be obtained in accordancewith the detected retreating speed and the acceleration-decelerationtime constant. In this case, this movement is automatically set as theposition deviation Ss. In consequence, both the screw retreating speedand the screw rotating speed are reduced, as shown in FIGS. 3A and 3B.

Since the retreat of the screw is based on a positioning command for thepreset metering completion position Sb, the screw is decelerated andlocated in the preset metering completion position Sb. If it is detectedthat the preset metering completion position Sb is reached by a currentposition Sa of the screw 3 (Step T9), therefore, the processor 26 readsa current rotational position Ra, which is obtained in accordance withthe position information fed back from the position/speed detector P1,through the servo interface 21, and stores it as a screw rotationalamount Rb at the end of the metering operation (Step T10).

If the rotation stop command is inputted so that the drive of the screwrotating servomotor M1 is stopped, as shown in FIG. 3, however, thescrew 3 cannot immediately stop, owing to the respective inertias of themotor M1, screw 3, screw drive mechanism, etc., and overruns before itstops. If the processor 26 detects this stopping of the rotation of thescrew 3 (Step T11), it detects the current rotational position Ra of thescrew 3, and stores it as a screw rotational amount Rs obtained when therotation of the screw 3 is stopped (Step T12).

The servo amplifier 23 is supplied with a rotation command for therotation of the screw 3 for the difference between the screw rotationalamount Rs obtained when the rotation of the screw 3 is stopped and thescrew rotational amount Rb at the end of the metering operation, in theopposite rotating direction (reverse to the screw rotating direction forthe metering process) at the preset rotating speed or the same speed asthe rotating speed for metering. Thus, the screw rotating servomotor M1is driven (Step T13), and the metering process is terminated.

After the metering operation is finished, as shown in FIG. 3, the screw3 is rotated reversely by the amount Ab corresponding to the overrunrotational amount Aa. Thus, the surplus metered resin quantity that isattributable to the overrun of the screw 3 is corrected, so that thepreset metered resin quantity can be obtained.

According to the embodiment described above, the screw rotational amountis detected by means of the position/speed detector that is connected tothe servomotor. Alternatively, however, it may be detected by means of adetector that directly detects the rotational amount of the screw.

According to the embodiment described above, moreover, the rotationalamount for the overrun is obtained from the difference between the screwrotational position Rb obtained in Step T10 at the end of the meteringoperation and the screw rotational position Rs obtained in Step T12 whenthe rotation of the screw is stopped. Alternatively, however, a counterfor counting pulses may be provided if the position/speed detector P1outputs the pulses. In this case, the counter is reset in Step T10, acounter value is read in Step T12, and the rotational amount for theoverrun is obtained from the counter value. Further, the time intervalfrom the completion of metering to the subsequent stop of screw rotationmay be measured. In this case, the overrun is calculated on the basis ofthe measured time and the screw rotating speed, and the calculated valueis regarded as a reverse rotational amount. In the operation shown inFIG. 4, in this case, moreover, a timer is started in Step T10, and thetimer is stopped and the time before the deceleration is stopped ismeasured in Step T12. In Step T13, the reverse rotational amount isobtained from the measured time and the preset rotating speed andoutputted.

If the overrun rotational amount Aa is previously given repetitionstability, it may be preset as the reverse rotational amount Ab so thatthe screw can be reversely rotated by the preset amount Ab immediatelyafter the screw rotation is decelerated and stopped. In the operationshown in FIG. 4, in this case, the processes of Steps T10 and T12 areunnecessary, and the process of Step T13 is a process for reverserotation by the preset rotational amount Ab. Also in this case, acommand speed for the reverse rotation may be automatically setaccording to the rotating speed for metering or may be set by anoperator.

Although the present invention is applied to an in-line injectionmolding machine according to the embodiments described above, it may bealso applied to a plunger-type injection molding machine. In this case,the screw advancing and retreating servomotor M2 serves as a plungeradvancing and retreating motor, and a plunger advances and retreats bymeans of the plunger advancing and retreating motor. The screw is simplyrotated by means of the screw rotating servomotor M1. Operation controlfor the metering process is carried out in like manner provided that theplunger advancing and retreating motor is drivingly controlled in placeof the screw advancing and retreating servomotor M2. Although thepresent invention is applied to a motor-driven injection molding machineaccording to the foregoing embodiments, it may be also applied to ahydraulic injection molding machine.

According to the present invention, the surplus metered resin quantitythat is attributable to overrun such that the screw rotates after theend of the metering operation, owing to the respective inertias of thescrew, screw rotation drive mechanism, etc., can be corrected, so that amore accurate preset metered resin quantity can be obtained. Inconsequence, molded parts can be equalized in weight, and stable moldingcan be enjoyed.

1. A control apparatus for an in-line injection molding machine, whichcomprises a screw advancing and retreating motor for advancing andretreating a screw and a screw rotating motor for rotating the screw,and is designed so that the screw rotating motor is rotated in a givendirection during metering operation as the screw advancing andretreating motor is driven to retreat the screw to a preset meteringcompletion position, the apparatus comprising: means for obtaining arotational amount which represents overrun of the screw during the timefrom the arrival of the screw at the preset metering completion positionto the subsequent deceleration and stop of the screw rotation; and meansfor driving the screw rotating motor to rotate the screw in a directionopposite to the direction for the metering operation in accordance withthe obtained rotational amount.
 2. A control apparatus for an in-lineinjection molding machine, which comprises a screw advancing andretreating motor for advancing and retreating a screw and a screwrotating motor for rotating the screw, and is designed so that the screwrotating motor is rotated in a given direction during metering operationas the screw advancing and retreating motor is driven to retreat thescrew to a preset metering completion position, the apparatuscomprising: means for previously setting and storing a rotational amountwhich represents overrun of the screw during the time from the arrivalof the screw at the preset metering completion position to thesubsequent deceleration and stop of the screw rotation; and means fordriving the screw rotating motor to rotate the screw for the storedrotational amount in a direction opposite to the direction for themetering operation after the screw rotation is stopped at the end of themetering operation.
 3. The control apparatus for an injection moldingmachine according to claim 1, wherein said means for rotating the screwin the direction opposite to the direction for the metering operationreversely rotates the screw immediately after the screw rotation isstopped.
 4. The control apparatus for an injection molding machineaccording to claim 1, wherein said means for rotating the screw in thedirection opposite to the direction for the metering operation drivesthe screw rotating motor to rotate the screw at a preset rotating speedin the direction opposite to the direction for the metering operation.5. The control apparatus for an injection molding machine according toclaim 1, wherein said in-line injection molding machine is replaced witha plunger-type injection molding machine, said screw advancing andretreating motor for advancing and retreating the screw is replaced witha plunger advancing and retreating motor for advancing and retreating aplunger, and the plunger is advanced and retreated in place of the screwby means of the plunger advancing and retreating motor.
 6. The controlapparatus for an injection molding machine according to claim 2, whereinsaid means for rotating the screw in the direction opposite to thedirection for the metering operation reversely rotates the screwimmediately after the screw rotation is stopped.
 7. The controlapparatus for an injection molding machine according to claim 2, whereinsaid means for rotating the screw in the direction opposite to thedirection for the metering operation drives the screw rotating motor torotate the screw at a preset rotating speed in the direction opposite tothe direction for the metering operation.
 8. The control apparatus foran injection molding machine according to claim 2, wherein said in-lineinjection molding machine is replaced with a plunger-type injectionmolding machine, said screw advancing and retreating motor for advancingand retreating the screw is replaced with a plunger advancing andretreating motor for advancing and retreating a plunger, and the plungeris advanced and retreated in place of the screw by means of the plungeradvancing and retreating motor.